/* SCCS Id: @(#)hacklib.c 3.1 91/11/25 */ /* Copyright (c) Stichting Mathematisch Centrum, Amsterdam, 1985. */ /* Copyright (c) Robert Patrick Rankin, 1991 */ /* NetHack may be freely redistributed. See license for details. */ /* We could only include config.h, except for the overlay definitions... */ #include "hack.h" /*= Assorted 'small' utility routines. They're virtually independent of NetHack, except that rounddiv may call panic(). return type routine name argument type(s) boolean digit (char) boolean letter (char) char highc (char) char lowc (char) char * lcase (char *) char * eos (char *) char * s_suffix (const char *) char * xcrypt (const char *) boolean onlyspace (const char *) char * tabexpand (char *) char * visctrl (char) const char * ordin (int) char * sitoa (int) int sgn (int) int rounddiv (long, int) int distmin (int, int, int, int) int dist2 (int, int, int, int) boolean online2 (int, int) boolean pmatch (const char *, const char *) int strncmpi (const char *, const char *, int) char * strstri (const char *, const char *) void setrandom (void) int getyear (void) char * get_date (void) int phase_of_the_moon (void) boolean friday_13th (void) int night (void) int midnight (void) =*/ #ifdef LINT # define Static /* pacify lint */ #else # define Static static #endif #ifdef OVLB boolean digit(c) /* is 'c' a digit? */ char c; { return((boolean)('0' <= c && c <= '9')); } boolean letter(c) /* is 'c' a letter? note: '@' classed as letter */ char c; { return((boolean)(('@' <= c && c <= 'Z') || ('a' <= c && c <= 'z'))); } #endif /* OVLB */ #ifdef OVL1 char highc(c) /* force 'c' into uppercase */ char c; { return((char)(('a' <= c && c <= 'z') ? (c & ~040) : c)); } char lowc(c) /* force 'c' into lowercase */ char c; { return((char)(('A' <= c && c <= 'Z') ? (c | 040) : c)); } #endif /* OVL1 */ #ifdef OVLB char * lcase(s) /* convert a string into all lowercase */ char *s; { register char *p; for (p = s; *p; p++) if ('A' <= *p && *p <= 'Z') *p |= 040; return s; } #endif /* OVLB */ #ifdef OVL0 char * eos(s) /* return the end of a string (pointing at '\0') */ register char *s; { while (*s) s++; /* s += strlen(s); */ return s; } char * s_suffix(s) /* return a name converted to possessive */ const char *s; { Static char buf[BUFSZ]; Strcpy(buf, s); if(!strcmpi(buf, "it")) Strcat(buf, "s"); else if(*(eos(buf)-1) == 's') Strcat(buf, "'"); else Strcat(buf, "'s"); return buf; } char * xcrypt(str) /* trivial text encryption routine (see makedefs) */ const char *str; { Static char buf[BUFSZ]; register const char *p; register char *q; register int bitmask; for (bitmask = 1, p = str, q = buf; *p; q++) { *q = *p++; if (*q & (32|64)) *q ^= bitmask; if ((bitmask <<= 1) >= 32) bitmask = 1; } *q = '\0'; return buf; } #endif /* OVL0 */ #ifdef OVL2 boolean onlyspace(s) /* is a string entirely whitespace? */ const char *s; { for (; *s; s++) if (*s != ' ' && *s != '\t') return FALSE; return TRUE; } #endif /* OVL2 */ #ifdef OVLB char * tabexpand(sbuf) /* expand tabs into proper number of spaces */ char *sbuf; { char buf[BUFSZ]; register char *bp, *s = sbuf; register int idx; if (!*s) return sbuf; /* warning: no bounds checking performed */ for (bp = buf, idx = 0; *s; s++) if (*s == '\t') { do *bp++ = ' '; while (++idx % 8); } else { *bp++ = *s; idx++; } *bp = 0; return strcpy(sbuf, buf); } char * visctrl(c) /* make a displayable string from a character */ char c; { Static char ccc[3]; c &= 0177; ccc[2] = '\0'; if (c < 040) { ccc[0] = '^'; ccc[1] = c | 0100; /* letter */ } else if (c == 0177) { ccc[0] = '^'; ccc[1] = c & ~0100; /* '?' */ } else { ccc[0] = c; /* printable character */ ccc[1] = '\0'; } return ccc; } #endif /* OVLB */ #ifdef OVL2 const char * ordin(n) /* return the ordinal suffix of a number */ int n; /* note: should be non-negative */ { register int dd = n % 10; return (dd == 0 || dd > 3 || (n % 100) / 10 == 1) ? "th" : (dd == 1) ? "st" : (dd == 2) ? "nd" : "rd"; } #endif /* OVL2 */ #ifdef OVL1 char * sitoa(n) /* make a signed digit string from a number */ int n; { Static char buf[13]; (void) sprintf(buf, (n < 0) ? "%d" : "+%d", n); return buf; } int sgn(n) /* return the sign of a number: -1, 0, or 1 */ int n; { return (n < 0) ? -1 : (n != 0); } #endif /* OVL1 */ #ifdef OVLB int rounddiv(x, y) /* calculate x/y, rounding as appropriate */ long x; int y; { int r, m; int divsgn = 1; if (y == 0) panic("division by zero in rounddiv"); else if (y < 0) { divsgn = -divsgn; y = -y; } if (x < 0) { divsgn = -divsgn; x = -x; } r = x / y; m = x % y; if (2*m >= y) r++; return divsgn * r; } #endif /* OVLB */ #ifdef OVL0 int distmin(x0, y0, x1, y1) /* distance between two points, in moves */ int x0, y0, x1, y1; { register int dx = x0 - x1, dy = y0 - y1; if (dx < 0) dx = -dx; if (dy < 0) dy = -dy; /* The minimum number of moves to get from (x0,y0) to (x1,y1) is the : larger of the [absolute value of the] two deltas. */ return (dx < dy) ? dy : dx; } int dist2(x0, y0, x1, y1) /* square of euclidean distance between pair of pts */ int x0, y0, x1, y1; { register int dx = x0 - x1, dy = y0 - y1; return dx * dx + dy * dy; } boolean online2(x0, y0, x1, y1) /* are two points lined up (on a straight line)? */ int x0, y0, x1, y1; { register dx = x0 - x1, dy = y0 - y1; /* If either delta is zero then they're on an orthogonal line, : else if the deltas are equal (signs ignored) they're on a diagonal. */ return((boolean)(!dy || !dx || (dy == dx) || (dy + dx == 0))); /* (dy == -dx) */ } #endif /* OVL0 */ #ifdef OVLB boolean pmatch(patrn, strng) /* match a string against a pattern */ const char *patrn, *strng; { char s, p; /* : Simple pattern matcher: '*' matches 0 or more characters, '?' matches : any single character. Returns TRUE if 'strng' matches 'patrn'. */ pmatch_top: s = *strng++; p = *patrn++; /* get next chars and pre-advance */ if (!p) /* end of pattern */ return((boolean)(s == '\0')); /* matches iff end of string too */ else if (p == '*') /* wildcard reached */ return((boolean)((!*patrn || pmatch(patrn, strng-1)) ? TRUE : s ? pmatch(patrn-1, strng) : FALSE)); else if (p != s && (p != '?' || !s)) /* check single character */ return FALSE; /* doesn't match */ else /* return pmatch(patrn, strng); */ goto pmatch_top; /* optimize tail recursion */ } #endif /* OVLB */ #ifdef OVL2 #ifndef STRNCMPI int strncmpi(s1, s2, n) /* case insensitive counted string comparison */ register const char *s1, *s2; register int n; /*(should probably be size_t, which is usually unsigned)*/ { /*{ aka strncasecmp }*/ register char t1, t2; while (n--) { if (!*s2) return (*s1 != 0); /* s1 >= s2 */ else if (!*s1) return -1; /* s1 < s2 */ t1 = lowc(*s1++); t2 = lowc(*s2++); if (t1 != t2) return (t1 > t2) ? 1 : -1; } return 0; /* s1 == s2 */ } #endif /* STRNCMPI */ #endif /* OVL2 */ #ifdef OVLB #ifndef STRSTRI /* A note on the #ifndef GCC_WARN: "const" unfortunately has two different * meanings. One meaning for "const char *str" is that the data pointed * to by "str" happens not to be modified by this function. That is true * for strstri. Another meaning is that "str" is (or may be) a pointer * to a constant string that must never be modified. gcc takes the latter * interpretation, and warns us about possible subversion of the const * modifier. Actually, that warning can be useful (we could accidentally * turn a constant string into a non-constant one with this function) * and so we note the fact that we're returning "str" as a non-const * by declaring it as non-const if GCC_WARN is defined. */ char * strstri(str, sub) /* case insensitive substring search */ #ifndef GCC_WARN const #endif char *str; const char *sub; { register const char *s1, *s2; register int i, k; # define TABSIZ 0x20 /* 0x40 would be case-sensitive */ char tstr[TABSIZ], tsub[TABSIZ]; /* nibble count tables */ # if 0 assert( (TABSIZ & ~(TABSIZ-1)) == TABSIZ ); /* must be exact power of 2 */ assert( &lowc != 0 ); /* can't be unsafe macro */ # endif /* special case: empty substring */ if (!*sub) return (char *) str; /* do some useful work while determining relative lengths */ for (i = 0; i < TABSIZ; i++) tstr[i] = tsub[i] = 0; /* init */ for (k = 0, s1 = str; *s1; k++) tstr[*s1++ & (TABSIZ-1)]++; for ( s2 = sub; *s2; --k) tsub[*s2++ & (TABSIZ-1)]++; /* evaluate the info we've collected */ if (k < 0) return (char *) 0; /* sub longer than str, so can't match */ for (i = 0; i < TABSIZ; i++) /* does sub have more 'x's than str? */ if (tsub[i] > tstr[i]) return (char *) 0; /* match not possible */ /* now actually compare the substring repeatedly to parts of the string */ for (i = 0; i <= k; i++) { s1 = &str[i]; s2 = sub; while (lowc(*s1++) == lowc(*s2++)) if (!*s2) return (char *) &str[i]; /* full match */ } return (char *) 0; /* not found */ } #endif /* STRSTRI */ #endif /* OVLB */ #ifdef OVL2 /* * Time routines * * The time is used for: * - seed for rand() * - year on tombstone and yymmdd in record file * - phase of the moon (various monsters react to NEW_MOON or FULL_MOON) * - night and midnight (the undead are dangerous at midnight) * - determination of what files are "very old" */ #if defined(AMIGA) && !defined(AZTEC_C) && !defined(__SASC_60) extern struct tm *FDECL(localtime,(time_t *)); #endif static struct tm *NDECL(getlt); void setrandom() { /* the types are different enough here that sweeping the different * routine names into one via #defines is even more confusing */ #ifdef RANDOM /* srandom() from sys/share/random.c */ srandom((unsigned int) time((time_t *)0)); #else # if defined(BSD) || defined(ULTRIX) /* system srandom() */ # ifdef BSD # if defined(SUNOS4) (void) # endif srandom((int) time((long *)0)); # else srandom((int) time((time_t *)0)); # endif # else # ifdef UNIX /* system srand48() */ srand48((long) time((time_t *)0)); # else /* poor quality system routine */ srand((int) time((time_t *)0)); # endif # endif #endif } static struct tm * getlt() { time_t date; #ifdef BSD (void) time((long *)(&date)); #else (void) time(&date); #endif #if (defined(ULTRIX) && !(defined(ULTRIX_PROTO) || defined(NHSTDC))) || defined(BSD) return(localtime((long *)(&date))); #else return(localtime(&date)); #endif } int getyear() { return(1900 + getlt()->tm_year); } char * get_date() { Static char datestr[7]; register struct tm *lt = getlt(); Sprintf(datestr, "%2d%2d%2d", lt->tm_year, lt->tm_mon + 1, lt->tm_mday); if(datestr[2] == ' ') datestr[2] = '0'; if(datestr[4] == ' ') datestr[4] = '0'; return(datestr); } /* * moon period = 29.53058 days ~= 30, year = 365.2422 days * days moon phase advances on first day of year compared to preceding year * = 365.2422 - 12*29.53058 ~= 11 * years in Metonic cycle (time until same phases fall on the same days of * the month) = 18.6 ~= 19 * moon phase on first day of year (epact) ~= (11*(year%19) + 29) % 30 * (29 as initial condition) * current phase in days = first day phase + days elapsed in year * 6 moons ~= 177 days * 177 ~= 8 reported phases * 22 * + 11/22 for rounding */ int phase_of_the_moon() /* 0-7, with 0: new, 4: full */ { register struct tm *lt = getlt(); register int epact, diy, goldn; diy = lt->tm_yday; goldn = (lt->tm_year % 19) + 1; epact = (11 * goldn + 18) % 30; if ((epact == 25 && goldn > 11) || epact == 24) epact++; return( (((((diy + epact) * 6) + 11) % 177) / 22) & 7 ); } boolean friday_13th() { register struct tm *lt = getlt(); return((boolean)(lt->tm_wday == 5 /* friday */ && lt->tm_mday == 13)); } int night() { register int hour = getlt()->tm_hour; return(hour < 6 || hour > 21); } int midnight() { return(getlt()->tm_hour == 0); } #endif /* OVL2 */ /*hacklib.c*/